Abstract: Systems and methods for global positioning satellite (GPS)/global navigation satellite system (GNSS) based real time global asset tracking are described. In an embodiment provides a system for real time, fast, global asset tracking, the system includes: a server with a processor, a memory, and a network interface, wherein the memory includes a tracking application, where the tracking application directs the processor to: receive a message including specific data from a tag; determine a time search window based on the message received from the tag; perform an initial position search; perform calculations for position and time, utilizing the time search window, the initial position search and satellite ephemeris information; and display a position information of the tag.

Abstract: Systems and methods for global positioning satellite (GPS)/global navigation satellite system (GNSS) based real time global asset tracking are described. In an embodiment provides a system for real time, fast, global asset tracking, the system includes: a server with a processor, a memory, and a network interface, wherein the memory includes a tracking application, where the tracking application directs the processor to: receive a message including specific data from a tag; determine a time search window based on the message received from the tag; perform an initial position search; perform calculations for position and time, utilizing the time search window, the initial position search and satellite ephemeris information; and display a position information of the tag.

Abstract: Systems and methods for global positioning satellite (GPS)/global navigation satellite system (GNSS) based real time global asset tracking are described. In an embodiment provides a system for real time, fast, global asset tracking, the system includes: a server with a processor, a memory, and a network interface, wherein the memory includes a tracking application, where the tracking application directs the processor to: receive a message including specific data from a tag; determine a time search window based on the message received from the tag; perform an initial position search; perform calculations for position and time, utilizing the time search window, the initial position search and satellite ephemeris information; and display a position information of the tag.

Abstract: There is provided an apparatus comprising an antenna (105) configured to receive a signal from a global navigation satellite system, wherein the antenna includes a first feed and a second feed; a hybrid coupler (110) including a first hybrid input, a second hybrid input, a first hybrid output, a second hybrid output, and wherein the first hybrid output is shifted in phase by 90 degrees relative to the second hybrid output; a variable phase shifter (150) including a shifter input and a shifter output, hybrid output; and a combiner (155) including a first combiner input, a second combiner input, and a combiner output, wherein the first combiner input is coupled to the shifter output, and the second combiner input is coupled to the second hybrid output, and wherein the combiner output is provided to detection circuitry (197).

Abstract: A technique for estimating the location of a wireless terminal at an unknown location in a geographic region. The wireless terminal measures samples of a predetermined form of energy in its vicinity. The disclosed technique then generates a characterization of a predetermined type of variation in the vicinity of the wireless terminal, based on the samples measured. Based on the characterization, the technique generates an estimate of whether the wireless terminal is moving or stationary. The technique then generates an estimate of the location of the wireless terminal, based on the estimate of whether the wireless terminal is moving or stationary. The location estimate can be based on i) applying a location estimate that is optimized for motion if the wireless terminal is estimated to be moving and ii) applying a different technique if the wireless terminal is estimated to be stationary.

Abstract: An indoor positioning system determines the location of a mobile device by comparing measured signal strengths to a database determined via offline calibration. Automated maintenance and repair of the database are facilitated by accurately characterizing indoor radio signal propagation. Systems and methods for generating spatially-dependent path-loss models are disclosed.

Abstract: An indoor positioning system determines the location of a mobile device by comparing measured signal strengths to a database determined via offline calibration. Automated maintenance and repair of the database are facilitated by accurately characterizing indoor radio signal propagation. Systems and methods for updating a signal strength database are disclosed. In one variation, a computer-implemented method of discovering a new or moved wireless access point (AP) within an indoor environment involves flagging one of the wireless APs as the new or moved AP; determining a location of the new or moved AP using information from at least one of an installation log and an AP location solver; determining transmit strengths and estimated received signal strengths of signals transmitted from calibration reference points (RPs) to the AP using a spatially-dependent path-loss model; and adding the transmit strengths and estimated received signal strengths to the signal strength database.

Abstract: An indoor positioning system determines the location of a mobile device by comparing measured signal strengths to a database determined during offline calibration. Automated creation, maintenance, and repair of the database are facilitated by accurately characterizing indoor radio signal propagation. Systems and methods for generating spatially-dependent path-loss models are disclosed.

Abstract: Systems and methods to track a device in an indoor environment having polygonal obstructions are disclosed.

Abstract: Systems and methods to generate safe zones and safe routes associated with a device are disclosed. These safe zones and safe routes can be used to map complicated location behavior into location behavior scores that can be applied systematically to tracking and authentication applications.

Abstract: A positioning method and system are provided. The positioning method includes the steps of utilizing at least one electronic device to establish a calibration database corresponding to an irregular grid of reference location points which are defined in an environment; utilizing a mobile device to detect Wi-Fi access points in the environment; utilizing the mobile device to estimate the signal strengths of the detected Wi-Fi access points to generate an estimated result; utilizing a positioning terminal to compare the estimated result and data stored in the calibration database by a weighed K-Nearest neighbor location algorithm to generate a comparison result; and utilizing the positioning terminal to estimate the location of the mobile device according to the comparison result.

Abstract: There is provided an apparatus comprising an antenna (105) configured to receive a signal from a global navigation satellite system, wherein the antenna includes a first feed and a second feed; a hybrid coupler (110) including a first hybrid input, a second hybrid input, a first hybrid output, a second hybrid output, and wherein the first hybrid output is shifted in phase by 90 degrees relative to the second hybrid output; a variable phase shifter (150) including a shifter input and a shifter output, hybrid output; and a combiner (155) including a first combiner input, a second combiner input, and a combiner output, wherein the first combiner input is coupled to the shifter output, and the second combiner input is coupled to the second hybrid output, and wherein the combiner output is provided to detection circuitry (197).

Abstract: Systems and methods to track a device in an indoor environment having polygonal obstructions are disclosed.

Abstract: Systems and methods to generate safe zones and safe routes associated with a device are disclosed. These safe zones and safe routes can be used to map complicated location behavior into location behavior scores that can be applied systematically to tracking and authentication applications.

Abstract: Systems and methods to generate safe zones and safe routes associated with a device are disclosed. These safe zones and safe routes can be used to map complicated location behavior into location behavior scores that can be applied systematically to tracking and authentication applications.

Abstract: Systems and methods to generate safe zones and safe routes associated with a device are disclosed. These safe zones and safe routes can be used to map complicated location behavior into location behavior scores that can be applied systematically to tracking and authentication applications.

Abstract: Systems and methods to track a device in an indoor environment having polygonal obstructions are disclosed.

Abstract: A database of Wi-Fi access point location data is built from (a) provisioning data; (b) GPS location estimates; and (c) inferred location estimates.

Abstract: A method for estimating the elevation of an wireless terminal inside of a tall structure is described that compensates for differences in temperature and atmospheric pressure between the inside and outside of the structure.

Abstract: A disclosed detector estimates the wireless terminal as being indoors or outdoors by utilizing information that includes measurement report data from previous calls involving both i) wireless terminals that are known to have been indoors and ii) wireless terminals that are known to have been outdoors while the measurement report data was collected. Based on this call data, one or more classification features are computed in accordance with the illustrative embodiment of the present invention. Then, for a wireless terminal that is to be classified during a call and with respect to the terminal being either indoors or outdoors, features that are representative of that wireless terminal for the call are evaluated against a characterization that is a composite of one or more previously-computed classification features. The features that are representative of the wireless terminal can be derived from the measurement reports received from the wireless terminal during the call.